Components of cholinergic excitation coupling with smooth muscle contraction in the guinea pig taenia coli]

In concentrations of 10(-9)-10(-7) g/ml acetylcholine increased the tone of the smooth muscles of the longitudinal band of the large intestine of a guinea pig, increasing the permeability of the cellular membranes for the entering flux of 45Ca2+. In concentrations of 10(-6) g/ml and over acetylcholine caused a release of the membranous calcium and in the concentrations of 10(-5)-10(-3) g/ml markedly increased the permeability of the membranes of the smooth muscle cells for the 22Na+ ions causing depolarization and an increase in the frequency of the action potentials. It is supposed that the coupling of the cholinergic stimulus with the end effect (muscle contraction) included 3 components: intensification of the entrance of Ca2+ into the smooth muscle cells, release of the membrane calcium and adhesion mechanism.     

Dexamethasone inhibits endotoxin-induced changes in calcium and contractility in rat isolated papillary muscle

This study investigates whether endotoxin-induced contractile dysfunction is associated with a defect in the modulation of calcium homeostasis and the potential mechanisms involved. Treatment of rats in vivo with endotoxin significantly decreased the magnitude of contractile transients in electrically stimulated left ventricular papillary muscle isolated after an equilibration period of 6 hours. Although no significant difference was found in the peak intracellular calcium concentration ([Ca2+]i) between the endotoxin-treated and control groups, resting [Ca2+]i) was significantly elevated in the endotoxin-treated group, producing a smaller Ca2+ transient (basal-peak difference) in this group. Pretreatment of rats with dexamethasone prevented the endotoxin-induced decrease in peak tension and inhibited the elevation in resting [Ca2+]i, with a resultant maintenance of Ca2+ transient magnitude. Similar observations were made during stimulation of the muscles by the beta-adrenoceptor agonist, isoprenaline. These results show that endotoxin-induced reduction of cardiac contractile performance is mediated, at least in part, by elevating resting [Ca2+]i, and a glucocorticoid protected from these negative effects. While endotoxin reduces the magnitude of the Ca2+ transient it does not alter peak [Ca2+]i availability. Further investigation is required to determine whether endotoxin decreases contractile performance by reducing the sensitivity of cardiac myofilaments to calcium.     

Effect of free fatty acids on the heart: effects of nonanoic acid on contractility and postextrasystolic potentiation in the rat papillary muscle

1. Nonanoic acid causes a depression in the contractile force of rat papillary muscles working isometrically. The effect depends on both the concentration of the fatty acid (0.1-1 mM) and the time of exposure (2-12 min), and shows a nearly complete reversibility. 2. Vmax-values derived from the force-velocity relation as well as the index of relation suggested by Meerson do not change in muscles exposed to nonanoic acid. During paired pulse stimulation with a 400 ms-delay of the second impulse, both the postextrasystolic potentiation and the time to reach a new steady level in the contraction amplitude are significantly increased. The speed of restituting the contraction after a twitch (resitution) is descreased. 4. The results suggest that the action site of nonanoic acid may be the excitation-contraction coupling system (including the action potential) rather than the contractile element or the relaxation of the muscle.     

Effect of ionophore A23187 on the strength of contraction and transmembrane action potential of guinea pig papillary muscle]

Calcium ionophore A23187 being added at 2.5 mM concentration induced 2--3-fold increase of peak contractile force of isolated guinea pig papillary muscle stimulated with the frequency of 0.2 Hz. The increase of force of contraction is not followed by any change in amplitude and duration of membrane action potential. A23187 decreases testing tension as well as duration of the twitch and increases relaxation rate of the muscle. This phenomenon probably reflects increased capability of sarcoplasmic reticulum in the process of calcium ion accumulation. In the presence of ionophore appearance of shoulder on the rising part of the twitch has been registered. In this case the single twitch being differentiated reveals two positive maxima. Addition of D-600 leads to decrease of action potential duration and eliminates the second part of the twitch, the amplitude and the velocity of the first phase of contraction being without change. It was proposed that the first component of the twitch appearing in the presence of A23187 and insensitive to D-600 corresponds to the release of calcium from some intracellular stores.     

Effects of intermittent hypoxia on action potential and contraction in non-ischemic and ischemic rat papillary muscle

Although it has been reported that intermittent hypoxia had the anti-arrhythmia effect, little is known about the effects on the action potential (AP) and contraction of papillary muscle, as well as the mechanism of anti-arrhythmia. The purpose of present study is to observe the effects of intermittent hypoxia on action potential and contraction of papillary muscle in rat left ventricle simultaneously using conventional intracellular microelectrode and contraction recording. The effects of intermittent hypoxia on AP and contraction during ischemic solution perfusion were also investigated. After exposed to intermittent hypoxia (six hours daily) for 42 days (IH42), duration (APD20) of 20%, 50% (APD50) and 90% (APD90) repolarization of AP prolonged significantly compared with animals in control (Con). Effective refractory period (ERP) in IH42 also prolonged significantly. Perfused with mimic ischemic solution, the changes of electric and mechanical activities in IH42 and in 28 days exposure to intermittent hypoxia (IH28) were much smaller than that in Con and IH14. The result of the study suggested that intermittent hypoxia prolonged the APD and ERP, offered the resistance against the ischemic damage on myocardium, which may be the electrophysiological basis of the anti-arrhythmia of intermittent hypoxia.     

Relation of mechanical noise in the rat papillary muscle to the level of its contraction

The existence of mechanical noise (MN) has been demonstrated in isolated papillary muscles of rats at rest. The mean amplitude of the MN was about 1 mg, the mean frequency 1.5 Hz (t 22 degrees C). A good agreement was found between the MN amplitude and the contracture level of the muscle. However, during long contractures, the correlation between the noise and contracture magnitude was disturbed. There was no relationship between the MN amplitude and contracture magnitude during exposures inducing metabolic alterations (hypoxia, NaCN) and upsetting the work of the sarcoplasmic reticulum (caffeine). It is believed that the MN amplitude is in a good agreement with the contracture magnitude and, therefore, with the concentration of intracellular Ca2+, if the sarcoplasmic reticulum and contractile elements of the cells are intact.     

离体心肌“生理性”收缩的计算机伺服系统

扩充了A/D接口的Z-80微机和编制的软件,与肌力计和力位移双态换能器组成伺服系统,可以自动控制换能器金属杆的工作状态和“后负荷”水平,使离体心肌产生时相顺序类同于射血心室的四个时相“生理性”收缩,从而获得心肌的张力长度关系、作功量等心肌力学信息,并可同步观察收缩末期张力长度关系和张力速度关系。     

Postrest contraction in the ventricular papillary muscle of spontaneously diabetic WBN/Kob rat.

In the present study, we investigated the characteristics of the postrest contraction (PRC) in chronic diabetic ventricular muscle. We used WBN/Kob rats of 7-8 weeks as the spontaneously diabetic animal and Wistar rats of 7-8 weeks as the control. We found: (1) No significant differences were seen in the amplitude, the contracting speed, and the relaxing speed of electrically stimulated twitch tension between control and WBN/Kob rats. In addition, the relationship between amplitude of twitch tension and stimulus cycle lengths (0.2-5 sec) was very similar in both animals. (2) The ratios of the first twitch tension (T1) of PRC with various rest intervals (5-600 sec) to the steady-state tension (Tss) were significantly smaller in the diabetic rats than in the controls. (3) When the preparation was stimulated at shorter cycle lengths, the recovery process of PRC was separated into at least two components (fast and slow components). In the diabetic rats, the time constant (tau) of both components was significantly longer than in controls. (4) After caffeine (10(-3) M) treatment, tau of the fast component in the control rats became longer, whereas it remained unchanged in diabetic rats. These findings suggest a dysfunction of the intracellular calcium handling system in spontaneously diabetic heart that is likely to include impaired calcium sequestration and/or extrusion.     

Implication of the nucleus in excitation contraction coupling of heart cells

In the present study, Fluo-3 Ca²⁺ measurement and confocal microscopy techniques were used in order to localize cytosolic [ ]_c and nuclear [ ]_n free Ca²⁺ distribution in resting and spontaneously contracting single heart cells from 10-day-old chick embryos. In resting single cells, the concentration of Ca²⁺ in the cytoplasm was lower than that in the nucleus. Increasing cytosolic free Ca²⁺ from 100–1600 nM gradually increased [Ca²⁺]_n with a maximum capacity near 1200 nM. Results from Fura-2 microfluorometry and Fluo-3 confocal microscopy suggest a potential cross talk between the increase of cytosolic free Ca²⁺ and the uptake and release of Ca²⁺ by the nucleus during spontaneous contraction of single myocytes. Calcium waves in spontaneously contracting cells were found to spread from one cell to the next with the nucleus acting as a fluorescent beacon in which Ca²⁺ levels remained elevated for several milliseconds even after cytosolic Ca²⁺ had returned to near basal values. These results strongly suggest that the nucleus plays a negative and positive feedback role in controlling cytosolic free Ca²⁺ concentration during excitation-contraction coupling in heart cells.     

Photoperiod-dependent modulation of cardiac excitation contraction coupling in the Siberian hamster

In mammals, changes in photoperiod regulate a diverse array of physiological and behavioral processes, an example of which in the Siberian hamster (Phodopus sungorus) is the expression of bouts of daily torpor following prolonged exposure to a short photoperiod. During torpor, body temperature drops dramatically; however, unlike in nonhibernating or nontorpid species, the myocardium retains the ability to contract and is resistant to the development of arrhythmias. In the present study, we sought to determine whether exposure to a short photoperiod results in alterations to cardiac excitation-contraction coupling, thus potentially enabling the heart to survive periods of low temperature during torpor. Experiments were performed on single ventricular myocytes freshly isolated from the hearts of Siberian hamsters that had been exposed to either 12 wk of short-day lengths (SD) or 12 wk of long-day lengths (LD). In SD-acclimated animals, the amplitude of the systolic Ca(2+) transient was increased (e.g., from 142 +/- 17 nmol/l in LD to 229 +/- 31 nmol/l in SD at 4 Hz; P < 0.001). The increased Ca(2+) transient amplitude in the SD-acclimated animals was not associated with any change in the shape or duration of the action potential. However, sarcoplasmic reticulum Ca(2+) content measured after current-clamp stimulation was increased in the SD-acclimated animals (at 4 Hz, 110 +/- 5 vs. 141 +/- 15 mumol/l, P < 0.05). We propose that short photoperiods reprogram the function of the cardiac sarcoplasmic reticulum, resulting in an increased Ca(2+) content, and that this may be a necessary precursor for maintenance of cardiac function during winter torpor.     

The action of ultrasound on the contraction strength and action potential of the papillary muscle of the rat heart

In experiments on isolated rat papillary muscles the effects of therapeutic doses of ultrasound (US) (intensity, less than 2 W/cm2) with frequency of 0.88 MHz on contraction force and action potential (AP) were studied. 12 muscles (from 14) responded to 3-min exposition of the US with a rise both in contraction force and in resting tension. Sensitivity to US and a value of inotropic effect changed significantly between the preparation, and the threshold intensities of US varied from 0.3 to 2 W/cm2. In 3 experiments the inotropic effect of US was more than 100%, but in others it was about 50%. Two preparations were not sensitive to the US. The positive inotropic effect of US was accompanied by membrane depolarization (up to 20 mV) and by prolongation of AP duration measured at 10% of its amplitude (APD10). The correlation between the increase in contraction force and APD10 was demonstrated. Some preparations responded to US with high depolarization (up to 50 mV) and were inexcitable. The US induced an increase in temperature less than 1 degree C, therefore all the effects of US could not be explained as a result of temperature rise.     

Two components of contraction in guinea pig papillary muscle

Biphasic contractions were produced in guinea pig papillary muscle by inducing partial depolarization in a K+ -rich solution (22 mM) containing 10(-6) M isoproterenol. However, when the same conditions were applied to frog and rat, monophasic contractions were obtained. In the case of guinea pig, an increase in the beating frequency produced an increase in amplitude of the first component and a reduction of the second, while in frog and rat, only a decrease in the amplitude of contractions was recorded. Caffeine (10(-3) M) eliminated the first component and increased the second in guinea pig, while in the case of rat and frog it decreased the amplitude of contractions. Procaine (10(-3) M) suppressed the first component and decreased the second one. The contraction in frog appears to be similar to the second component of contraction in guinea pig, while in rat, the contraction is comparable with the first component in guinea pig. It is suggested that the calcium ions which activate the two components of contraction in guinea pig under the given experimental conditions may arise from two different sources.     

Calcium channels and excitation-contraction coupling in cardiac cells. I. Two components of contraction in guinea-pig papillary muscle

Biphasic contractions have been obtained in guinea-pig papillary muscle by inducing partial depolarization in K+-rich solution (17 mM) containing 0.3 microM isoproterenol; whereas in guinea-pig atria, the same conditions led to monophasic contractions corresponding to the first component of contraction in papillary muscle. The relationships between the amplitude of the two components of the biphasic contraction and the resting membrane potential were sigmoidal curves. The first component of contraction was inactivated for membrane potentials less positive than those for the second component. In Na+-low solution (25 mM), biphasic contraction became monophasic subsequent to the loss of the second component, but tetraethylammonium unmasked the second component of contraction. The relationship between the amplitude of the first component of contraction and the logarithm of extracellular Ca2+ concentration was complex, whereas for the second component it was linear. When Ca2+ ions were replaced by Sr2+ ions, only the second component of contraction was observed. It is suggested that the first component of contraction may be triggered by a Ca2+ release from sarcoplasmic reticulum, induced by the fast inward Ca2+ current and (or) by the depolarization. The second component of contraction may be due to a direct activation of contractile proteins by Ca2+ entering the cell along with the slow inward Ca2+ current and diffusing through the sarcoplasm. These results do not exclude the existence of a third "tonic" component, which could possibly be mixed with the second component of contraction.